WO2017207703A1

WO2017207703A1 - Battery

Info

Publication number: WO2017207703A1
Application number: PCT/EP2017/063330
Authority: WO
Inventors: Thomas Krämer
Original assignee: E-Seven Systems Technology Management Ltd
Priority date: 2016-06-03
Filing date: 2017-06-01
Publication date: 2017-12-07
Also published as: PL3465797T3; WO2017207701A1; EP3465797B1; EP3465797A1

Abstract

The invention relates to a battery (2) having a cell arrangement (1), wherein the cell arrangement (1) has multiple battery cells (5), wherein the cell arrangement (1) has at least two battery sections (6), and each battery section (6) is composed of multiple battery cells (5). According to the invention, between at least two adjacent battery sections (6), there is arranged an at least partially electrically and thermally conductive contacting section element (7) with a first side and with a second side, which contacting section element has, on the first side and on the second side, in each case at least one electrically and thermally conductive contacting section, wherein the end connectors facing toward the first side of the contacting section element (7) are connected in electrically and thermally conductive fashion to the at least one contacting section of said first side, and wherein the end connectors facing toward the second side of the contacting section element (7) are connected in electrically and thermally conductive fashion to the at least one contacting section (21) of said second side, and wherein end connectors of the battery cells (5) are connected in electrically and thermally conductive fashion to one another by means of the contacting section element (7), such that an electrical current and a flow of heat are distributed over the entire cell arrangement (1).

Description

battery

The present invention relates to a battery having a cell arrangement, the cell arrangement having a plurality

Battery cells, wherein the cell assembly has at least two battery sections and each

Battery section consists of a plurality of battery cells, each battery cell having a first and a second end terminal and wherein between the first and the second end terminal of each battery cell a

Battery cell longitudinal axis runs, the

Battery cell longitudinal axes of each battery section are each aligned parallel to each other, and wherein the

Battery sections are arranged adjacent to each other. Such batteries are known in the art

Well known and come for many purposes

Commitment. Batteries of different sizes and with a different number of parallel and serially connected battery cells are known from the prior art, whereby the batteries provided by the battery

Capacity and that provided by the battery

Voltage can be adapted to the respective application. An especially important purpose for the present invention is the use of batteries in electrically powered motor vehicles. But such batteries can also be used in many other applications. The battery cells may be primary or

Secondary cells act, the battery is often referred to when using secondary cells as a battery pack. From the prior art are different

Battery cell types known, which differ mainly by the electrode materials used for the battery cells and electrolytes. Currently, battery packs with lithium-ion battery cells and nickel-metal hybrid battery cells are used in many applications.

Usually, battery cells of a battery cell type are used for a battery. It is also possible and convenient for some applications, battery cells

use different battery cell types.

Especially for large batteries, for example for

Operation of electrically driven motor vehicles, in which a plurality of battery cells is used, occur within the battery, inter alia, when loading

comparatively high currents areas with high

Temperatures through which the charging or

Discharge in the high temperature area

arranged battery cells and their life

being affected. The areas of elevated or high temperatures are also referred to as thermal hotspots. The temperature distribution within the

Cell arrangement is determined by a variety of factors such as the type of battery cells used, the relative arrangement of the battery cells to each other, the charging or flowing through the battery cells

Discharge current and the aging state of the respective

Battery cell influenced. As an object of the invention, it is considered to provide a battery in which the occurrence of

Temperature hot spots within the battery is avoided.

The object is achieved in that between at least two adjacent battery sections an at least partially electrically and thermally

conductive Kontaktierungsabschnittselement is arranged with a first side and a second side, which on the first side and on the second side in each case at least one electrically and thermally conductive

Contacting portion, wherein the

Battery sections are arranged to each other so that each battery section, a plane can be assigned, which is perpendicular to the battery cell longitudinal axes of the

Battery cell of the battery section passes through at least one of the battery cells of the battery section and wherein through this plane to the battery section

adjacent battery sections are not cut, the first side of this

Kontaktierungsabschnittselements facing end terminals are electrically and thermally conductively connected to the at least one contacting portion of this first side, wherein the second side of this

Kontaktierungsabschnittselements facing end terminals are electrically and thermally conductively connected to the at least one contacting portion of this second side and wherein end terminals of the battery cells via the

Kontaktierungsabschnittselement electrically and thermally conductively connected to each other, so that a electrical current and heat flow are distributed throughout the cell array.

The battery cells of different battery sections are arranged so that they never completely

are arranged side by side. Individual battery cells of different battery sections may be partially laterally offset from battery cells adjacent

Be arranged battery sections. However, the battery cells of adjacent battery sections can not

completely juxtaposed, otherwise there is no plane perpendicular to the

Battery cell longitudinal axes of a battery section passes through at least one of the battery cells of the battery section and thereby no battery cells adjacent

Battery sections cuts.

A large part of the thermal energy produced in the battery cells is conducted through the entire cell arrangement via the end terminals of the battery cells in the construction according to the invention. In this case, a distribution of electrical and thermal energy between the

Battery cells via the Kontaktierungsabschnittselemente. The end connections of the battery cells are suitable for

Transmission of thermal energy in a special way, since they are thermally conductively connected to an interior of the battery cells and even from an electric and

consist thermally well conductive material. On the other hand, cooling and heat dissipation via a cell jacket of a battery cell is often less efficient, since the cell jacket usually consists of a thermally and electrically poorly conductive material. If the battery cells are uniform in terms of their electrical and thermal conductivity, results in a uniform distribution of

electric current and the heat flow within the

Battery cells. If the thermal conductivity and / or the resistance of one or more battery cells is reduced, then it is achieved by the construction that an electric current and a heat flow are evenly distributed within the battery, at least through the remaining battery cells. A uniform distribution of electric current and heat flow helps to avoid hotspots within the battery.

According to the invention, it is possible to distribute thermal energy from the battery cells over the individual battery sections between the battery sections and the individual battery cells. Furthermore, it is possible by the cell arrangement according to the invention, a

distribute electric current evenly to the battery cells. A uniform distribution of the current contributes to a uniform heat distribution within the battery, as a battery cell is heated more by a higher current. If the temperature of a battery cell changes, so does its electrical

Resistance. Thus, the electrical influence

Resistance and the temperature of the battery cells within a battery mutually. It follows that it is particularly important to distribute both the electric current and the thermal energy within a battery evenly on their battery cells. According to the invention, in each case one contacting-section element is arranged between two battery sections. This is an electrically and thermally at least partially conductive body. This has, at least in sections, areas that as

Contacting sections are suitable. Battery cells of the battery are electrically and thermally conductively connected to the contacting sections. It can do that

Contacting section element different

have geometric configurations. By the

Kontaktierungsabschnittselement is a contact de: battery cells and a distribution of an electric current and a heat flow between the with the

Kontaktierungsabschnittselement electrically and thermally conductively connected battery cells through the

Contacting section element are enabled. The Kontaktierungsabschnittselement is preferably rigid.

The battery cells within each battery section may be coincident with respect to their battery polarity. Thus, all of the battery cells within a battery section may be aligned so that they each have a first terminal that forms a positive battery terminal, a first

Contacting a contacting portion member and having a second end terminal forming a negative battery terminal, a second contacting portion member

to contact. However, the battery cells do not necessarily have to be in view of their battery polarity

be aligned consistently. So it is also possible that on a Kontaktierungsabschnittselement on a Side both Batteriepluspole and Batterieminuspole abut.

It is preferred if the with the at least one

Contacting section of the first page connected

End connections with each other via the

Kontaktierungsabschnittselement electrically and thermally conductively connected to each other, wherein the connected to the at least one contacting portion of the second side end connections with each other via the

Kontaktierungsabschnittselement electrically and thermally conductively connected to each other, and wherein the connected to the at least one contacting portion of the first side end terminals electrically and thermally

conductive with those with the at least one

Contacting portion of the second side connected end terminals are connected via the Kontaktierungsabschnittselement, so that the battery cells in a

electrical series and parallel circuit are electrically conductively connected to each other and are also thermally conductive interconnected. It has

pointed out that in such a circuit, a particularly uniform distribution of heat and

electric current enters all battery cells of the battery.

Preferably, adjacent battery sections

spaced apart from one another in the direction of a battery cell longitudinal axis of one of the adjacent battery sections. The distance between the

Battery sections can through the

Contacting section element are made. According to this spatial configuration, the battery cells of different battery cells can not be arranged side by side in a direction perpendicular to the battery cell longitudinal axes, but are always offset from each other in the direction of a battery cell longitudinal axis of one of

adjacent battery sections spaced from each other.

According to the invention it is also possible that the

Battery cells of adjacent battery sections so

are arranged that at least one by one

Battery cell of a battery section extending axis, which runs parallel to a battery cell longitudinal axis of this battery cell, a battery cell in one

adjacent battery section cuts.

Thus, the battery cells are adjacent

Battery sections arranged to each other so that cross sections of the battery cells at least partially

overlap when a cross section of a battery cell is displaced in the direction of the battery cell longitudinal axis of this battery cell.

Furthermore, it can be provided according to the invention that the battery cells of adjacent battery sections lie opposite each other on a contacting section element. This assumes that the arrangement of the

Battery cells in adjacent battery sections

matches. According to the invention, however, it is also possible that the battery cells are arranged differently in adjacent battery sections to each other. Accordingly, some or all of the battery cells may be so on the

Contacting section element abut that each on an opposite side of the Kontaktierungsabschnittselements no battery cell of a neighboring battery section is applied.

It is particularly preferred if the battery cells of all battery sections of the battery are parallel to one another

having aligned battery cell longitudinal axes. Thus, all the battery cells in a battery have one

matching alignment towards one

Battery axis on. Due to this construction, a battery constructed in this way can absorb forces which are exerted on the battery in the direction of the battery axis particularly well. Such a construction is particularly advantageous when the battery cells adjacent

Battery sections are all arranged opposite each other on the Kontaktierungsabschnittselement. Thus, forces from a battery cell in the direction of

Battery axis are transmitted via the Kontaktierungsabschnittselement in an advantageous manner to an opposite battery cell in an adjacent battery section.

If all the battery cells of the battery have mutually parallel aligned battery cell longitudinal axes, it is advantageous if the battery sections of the battery are arranged one behind the other along a battery axis, which runs parallel to the battery cell longitudinal axes. The battery sections are thus not arranged to each other in a direction perpendicular to this battery axis.

Forces within the battery can be transmitted particularly well along the battery cell longitudinal axes of the battery cells throughout the cell assembly. It is especially beneficial if all

Battery sections of the battery lie in a battery compartment, wherein a battery compartment cross-section of the battery compartment perpendicular to the battery axis a maximum

Battery section cross-section of a

Battery section envelope of a battery section perpendicular to the battery axis corresponds, wherein the maximum battery section cross section of the

Battery section cross-section of a battery section is the all battery section cross-sections of all

Includes battery sections along the battery axis. The battery section envelopes are going through

Formed lateral surfaces of the respective outer battery cells of the respective battery section. By a battery section is thus a cross section of a

Defined battery section whose area is either just as large or larger than the area of the cross sections of all other battery sections of the battery.

Preferably, the first end connections form the

Battery cells battery plugs and the second

End connections of the battery cells form battery mini-poles, the battery cells of a battery section being connected to a contacting-section element in each case exclusively via battery positive poles or exclusively via battery mini-poles. This is a

Kontaktierungsabschnittselement preferably on a first side exclusively on Batteriepluspole and on a second side exclusively via battery inlets

contacted. This allows an electrical and

thermal parallel and series connection within the battery across all battery cells and all Contacting section elements within the battery. Below are first end connections of the

Battery cells that form Batteriepluspole be referred to as positive end connections. Second end terminals of the battery cells that form battery mini-spikes are referred to below as negative end terminals.

According to a particular embodiment of the invention, the Kontaktierungsabschnittselement is plate-shaped

educated. A plate-shaped

Contacting section element is characterized by a small depth in relation to its height and width. A plate-shaped Kontaktierungsabschnittselement can be particularly easy between adjacent

Arrange battery sections to these with each other

electrically and thermally conductive to connect. All

Contacting sections of a plate-shaped

Contacting section element on one side of the

Kontaktierungsabschnittselements run in a plane. Alternatively, the Kontaktierungsabschnittselement may not be plate-shaped, but only have planar portions which are arranged stepwise offset from each other on the Kontaktierungsabschnittselement. In this case, it is advantageous to have a contacting section element which has contacting sections on both sides, which are arranged staggered from one another in a stepped manner. The contacting portion member may be formed so that contacting portions provided thereon on one side of the contacting portion into two

different levels or in more than two

different levels are arranged. Preferably, a battery start region and a battery end region of the cell assembly are each one

Pressure plate arranged, with the printing plates over

Tension elements are connected to each other and thereby applied to the at least one Kontaktlerungsabschnittselement battery cells to the at least one

Press contactor portion element, and wherein the battery start region and the battery end region are defined by end connections at a first end and at a second end of the cell assembly. The components within the cell assembly are thereby pressed together. The pressure plates exert a contact pressure on the battery cells. The pressure plate can

According to the invention, the contact pressure on the

Battery start area or at the

Apply the battery end area directly to the battery cells. So the pressure plate can directly on

Abut the end terminals of the battery cells. The pressure plate can be the contact force at the battery start area

alternatively, however, also indirectly exert on the battery cells at the battery end region. So can between the pressure plate and the battery cells

According to the invention, an additional layer can be provided. This additional layer may be electrically non-conductive and / or elastic. Furthermore it can

be provided that between a pressure plate and a battery start region or a

Batterieendbereich a Kontaktlerungsabschnittselement is arranged.

According to the printing plates can be formed flat, but there are also different designs of Printing plates possible. The tension elements are each connected to the pressure plates. Here are the tension elements

in such a way clamped between the pressure plates that they exert a tensile force on the printing plates. Due to the tensile force, the pressure plates in turn can exert the already described contact pressure on the cell assembly. The contact force is transmitted across all battery sections of the cell assembly within the battery. As a result, the battery cells are particularly well contacted with the at least one Kontaktierungsabschnittselement within the cell assembly, because by a high

Contact pressure, a contacting area between the Kontaktierungsabschnittselementen and end terminals of the battery cells is increased.

The tension elements can be designed as rods, as tubes or as other elongated elements. Preferably, the rods are made of a metal, most preferably made of steel. However, the rods may alternatively be made of a particularly stable plastic or of a composite material.

By pressing, an electric current and a heat flow can be distributed particularly well within the battery. Furthermore, the battery is characterized in a

stabilized special dimensions, so that they can withstand strong mechanical loads. This is

especially advantageous if a battery is regularly exposed to such mechanical stresses.

Preferably, the battery cells are in the

Battery sections in first and second cell levels arranged, wherein the first and the second cell planes are arranged alternately within a battery section, wherein at least two along each cell plane

Battery cells are arranged, wherein between adjacent battery cells in the first cell level and adjacent battery cells in the second cell level, a same

Spacing is predetermined, wherein the battery cells are arranged offset in the first cell plane to the battery cells in the second cell plane, and wherein the

Battery cells are arranged identically in all battery sections, so that within the lateral surface

at least one outer passage portion is formed through which one of the tension elements is passed. The battery cells in a first cell level or in a second cell level can be spaced from each other as desired. They can be so far from each other

be spaced that inner passage sections are present in the cell assembly, by the tension elements

can be passed.

According to a further embodiment of the invention, the battery cells are located in corner regions of the battery sections on two other battery cells and in edge regions of the battery sections to three or four other battery cells, all battery cells that are not in one

Corner region or a peripheral region are arranged to abut six other battery cells and each

Contacting portion has a matching cell assembly, so that within the lateral surface at least one outer passage portion is formed through which one of the tension elements is passed. According to this arrangement, the battery cells are adjacent to each other directly, which makes them especially well packed. It is therefore possible to arrange a particularly large number of battery cells in each battery section. In this case, outer passage sections between the battery cells and a jacket surface enclosing the battery cells result. However, according to the invention, deviating arrangements of the battery cells within the battery sections are also possible

possible. According to the invention, in each case at least one battery cell can be removed within the battery sections, so that at least one inner passage section is formed within the lateral surface, through which one of the tension elements is passed. The removal of an additional battery cell is both in a staggered arrangement of the battery cells as well as in any other arrangement of the battery cells within the battery

possible. As a result, additional space can be obtained within the battery, which can serve as a passage section.

It is advantageous if the pressure plates are designed as metal plates. Metal plates are sufficiently stable so that a tensile force can be transmitted from the tension members to the cell assembly. The metal plates can be made different thickness depending on a desired tensile force. Will be a high

Traction desired, the metal plate must be made particularly thick. Preferably, the metal plate is made 3 to 20 mm thick, most preferably it is made 5 mm thick. The metal plates can

According to the invention of copper, aluminum or a be formed other very good thermal conductivity material. Alternatively, it is possible not to make the printing plates of metal. So can the printing plates

According to the invention be made of a hard plastic.

Preferably, the tension elements are passed through recesses in the pressure plates, wherein the tension elements are screwed into the pressure plate and / or are screwed by means of nuts to the pressure plates. A

Screw connection allows a precise exerted by the tension elements on the pressure plates pulling force

adjust. However, according to the invention, other fixing means can also be used in order to fix the tension elements to the recesses in such a way that the tension elements have a

Exert tensile force on the printing plates. According to the invention, it is possible that the tension elements are made of an electrically non-conductive material. In this way, it can be prevented that an electric current is passed over the tension elements. This is especially true at

Embodiments of the invention of importance in which the printing plates carry electrical power. Alternatively, it is possible that the tension members are coated with an electrically non-conductive material to electrically isolate the tension members.

Preferably, the tension elements are connected to the pressure plates in such a way that on each pressure plate by the tension elements connected to it a compressive force of

at least 50 N, preferably at least 100 N and particularly preferably at least 200 N in the direction of

Battery sections is exercised. This will be the Battery cells and the contactor section elements within the battery flow and flow particularly well

thermally conductive contacted with each other. In addition, the cell arrangement is particularly stable when a correspondingly high tensile force is exerted on the cell assembly.

At least one pressure plate preferably has cooling ribs. Cooling ribs increase the surface area of the printing plates so that the printing plates can dissipate heat better. Thus, from the end faces of the battery heat from the cell assembly on the pressure plates in

be discharged advantageously. Cooling fins are particularly suitable when the pressure plates made of a metal such as copper or aluminum.

Preferably, end terminals of one battery section lie directly at end terminals of an adjacent one

Battery section electrically and thermally conductive. It is very particularly preferred positive

End connections directly to negative end terminals of a neighboring battery section. Accordingly, two or more battery cells are connected in series, without causing directly adjacent battery cells by a

Kontaktierungsabschnittselement are separated from each other. Such a structure can be provided when a sufficient distribution of an electric current and a heat flow within a battery also with a

small number of Kontaktierungsabschnittselementen

within the cell arrangement is possible. Whether this is the case will be determined by capacitive and others

Characteristics of the battery cells determined. According to a particular embodiment of the invention, the battery cells are designed as round cells. Round cells have a cylindrical base body with arranged on the opposite side surfaces end terminals. Round cells point within one

Battery arrangement over a conventional

cuboid coffee bag cell has the advantage that within a cell assembly between the round cells due to their geometry cavities are present. These cavities are particularly advantageous when it

There is a malfunction within the battery where one or more battery cells burst or even explode. In a conventional battery assembly with one or more coffee-bag cells, there is no space within the battery in which the bursting or exploding battery cells can expand. The

Excess energy can not be dissipated, resulting in a battery array with many cells in the

worst case, an explosion of the entire battery threatens. In a cell arrangement based on

Round cells this risk is significantly reduced.

According to a particular embodiment of the invention, at least one positioning plate is arranged in the cell arrangement, through which the battery cells of the

Battery section are passed, wherein the

Positioning plate has a recess through which the battery cells are passed, and wherein the recess is defined by an envelope around the battery cells of the battery section, so that the recess surrounds the battery cells form-fitting to the

Position battery cells inside the battery and to stabilize. It touches an edge surface of the

Recess not necessarily all battery cells that are passed through the recess. On too

Battery cells that are not from one side of the

Recess will be indirectly touched

stabilizing effect by adjacent battery cells exerted directly on a side surface of the

Recess abut. The positioning plate can be made of metal, plastic, wood or other material. The positioning plate may alternatively not only have a recess, but a contiguous surface having a plurality of recesses, wherein through each recess at least one battery cell

and wherein each recess is defined by an envelope around the at least one battery cell passed therethrough so that the recess positively engages around the at least one battery cell to position and stabilize the at least one battery cell within the battery.

It is beneficial if at everyone

Contacting section element on both sides in each case a positioning plate is arranged. As a result, the battery cells are stabilized particularly well in the areas of the battery, in which they

Contact contacting section elements.

In particular, if the Kontaktierungsabschnittselemente has specially designed Kontaktierungsbereiche where it is to contact, such an arrangement of the positioning plates is advantageous. The positive ones

End connections and the negative end connections can then be positioned particularly accurately in the area of Kontaktlerungsabschnittselemente.

Preferably, at least one

Kontaktlerungsabschnittselement thermally conductively connected via a heat dissipation element with a heat sink. The heat sink should be outside the battery, but may also form part of the battery. By means of a correspondingly arranged heat removal element, a heat flow can be removed from the cell arrangement.

The cell arrangement can be enclosed according to the invention by a thermally conductive housing. Since the housing is thermally conductive, it is useful as a heat sink to absorb heat from the cell assembly and optionally transmit it to other heat sinks to which e is thermally conductively connected. The heat dissipation element described above may be thermally conductively connected to the housing. The housing is preferably made of a metal, especially

preferably of iron, aluminum or a metal alloy. Such a housing is suitable for protecting the cell assembly from external influences. The housing preferably has two openings onto which the

Pressure plates are placed. The housing can

According to the invention elongated recesses as

Have ventilation slots.

The Kontaktlerungsabschnittselement may be formed according to the invention as a metal body. It is particularly preferred if the metal body is made of copper or aluminum. Metal bodies have one excellent electrical and thermal conductivity. A plurality of battery cells can be connected in parallel and in series by a metal body. The

Contacting sections on the metal body need not have any particular configuration. You can

According to the invention, however, be designed as elevations or have elevations. The metal body may be plate-shaped or have a stepped surface. Deviating geometric configurations of the metal body are also possible according to the invention.

According to a further embodiment of the invention, the Kontaktierungsabschnittselement is as a

Conductor element is formed, which consists partly of a non-electrically conductive material, wherein the conductor forming element on a first side and on a second side each having at least one electrically and thermally conductive contacting portion, and wherein each contacting portion with each other

Contacting portion is electrically and thermally conductively connected. For this purpose, according to the invention in the non-electrically conductive material of

Kontaktierungsabschnittselements be embedded electrically and thermally conductive materials. The

Conductor element allows to make an electrical and thermal connection of the battery cells. When executed as a conductor forming element

Contacting section element is special

advantageous if the battery cells of the battery are pressed with a comparatively high force to this, so that a particularly good electrical and thermal

Conductive connection between the battery cells and the arises the Kontaktierungsabschnittselement. In which

Conductor element may be a circuit board. However, it may also be a spatially deviant element. That's how it works

Ladder element according to the invention have a cuboid shape or another shape.

According to the invention, a core made of an electrically and thermally conductive material can be arranged in a planar manner in the non-electrically conductive material of the conductor formation element, with the sides of the non-electrically conductive material facing away from the core in each case

at least one contacting portion is arranged, and wherein at least one electrically and thermally conductive feedthrough element through the core and on both sides of the core, not electrically

conductive material extends, the

Feedthrough element is electrically insulated from the core and electrically conductive with the at least one

Contacting portion on the first side and is connected to the at least one contacting portion on the second side, so that an electrically and thermally conductive connection of the contacting portions on the first side with the contacting portions on the second side is made by the feedthrough element and a heat flow absorbed by the core and can be removed from the conductor forming element. Thus, in a battery with such

Conductor element not only an electric current and a heat flow are distributed in the cell assembly of the battery, but also be absorbed by the core. This makes it possible, the heat flow from the Conductor element and thus also dissipate from the cell assembly on the core. According to the invention, the core can be led out of the conductor formation element and connected in a thermally conductive manner to a heat sink. Alternatively, the thermally conductive core with a

Heat dissipation element to be connected, which is thermally conductively connected to a heat sink.

The battery may be further configured such that at least two contacting portions and an electrically and thermally conductive connecting portion are disposed on the first side of the conductor forming member therein electrically and thermally conductively connecting the contacting portions on the first side to each contacting portion on the first Side is associated with an electrical fuse and that the connecting portion is connected to each contacting portion via an electrical fuse associated with this contacting portion, wherein the connecting portion with the at least one contacting portion on the second side by the electrically non-conductive

Material of the board is electrically conductively connected via an electrically conductive feedthrough element, so that each contacting portion on the first side opposite to each other contacting portion on the first side of the conductor forming element and opposite each contacting portion on the second side of the

Conductor element is secured by at least one electrical fuse. Thus, the

Battery cells opposite each other by means of

Secure ladder element electrically. This is

Especially advantageous if a resistance of a Battery cell collapses due to a fault, so that too much current flows through this battery cell. In this case, an electrical fuse is triggered, which is associated with a contacting portion of the conductor forming element, which is electrically and thermally conductively connected to a positive or negative terminal of this battery cell. As a result, this defective battery cell is electrically isolated from the cell arrangement.

Preferably, under each contacting section of

Conductor element arranged an elastic material which under the action of a pressing force on the

Contacting portion is elastically deformable. The elastic material may be arranged according to the invention in the non-conductive material of the conductor forming element under the contacting section. Will one

Pressing force applied to the contacting portion, both the contacting portion and the elastic material are deformed. Thus, it is possible to have a particularly good electrical and thermal conductivity

Establish connection between a contacting portion and a battery cell. Due to the local

Deformation of the conductor element element can its

unwanted deformation in other sections or even damage to the conductor forming element can be avoided when battery cells are pressed down to the contacting sections. According to an alternative

Embodiment may be a material from which the

Contacting section is made to be elastic. Thus, a contacting section of the

Conductor element of an elastic material be formed, which is electrically and thermally conductive.

It is further preferred if the

Kontaktierungsabschnittselement, in particular when it is designed as a conductor forming element, at its

Contacting sections having spring elements. The spring elements may consist of an electrically and thermally conductive material, for example of a metal. The spring elements are electrically and thermally conductive with the Kontaktierungsabschnitten the

Contacting section element connected. Due to the chosen material and its structure are the

Spring elements elastically deformable. The spring elements can, according to possible embodiments of the invention coil springs or springs from a

sponge-like material or be of an elastic fabric. They serve to improve the contact between the battery cells of the battery and the

Establish contacting section element. In addition, they allow a balancing of the contact forces between the battery cells and the Kontaktierungsabschnittselementen within the battery, so that an undesirable

sectional deformation of the

Contacting section element is prevented. Furthermore, a more uniform contact pressure on all

Battery cells of a battery section made when the cell assembly is pressed. This is desirable, as this electrical and thermal

Transition resistances between the battery cells and the Kontaktierungsabschnittselementen be reduced. Further embodiments of the invention are in the

Drawings shown. Showing:

1 is a schematic representation of a cell arrangement of a battery according to the invention,

Fig. 2 is a schematic representation of a portion of the cell assembly of the battery of FIG. 1 in a

Cut looks,

FIG. 3 is a schematic representation of a contactor section element embodied as a board in a view of a first side of the first embodiment. FIG

Contacting section element,

Fig. 4 is a schematic representation of the

Kontaktlerungsabschnittselements according to FIG. 3 in a

View on a second side of the

Contacting section element,

Fig. 5 is a schematic representation of a cross section of a running as a circuit board

Contactor section element with a

Implementing recess

Fig. 6 is a schematic representation of a surface

formed Kontaktlerungsabschnittselements with adjoining battery cells in a side view,

Fig. 7 is a schematic representation of a

Kontaktierungsabschnitts with stepped trained Surfaces with adjacent battery cells in a side view,

Fig. 8 is a schematic representation of a

battery according to the invention with a housing,

FIG. 9 is a schematic illustration of a contactor portion member formed as a circuit board with a circular array of traction element recesses in a view of a first side of the invention. FIG

Contactor section element and

Fig. 10 is a schematic representation of one as a

Board configured Kontaktlerungsabschnittselements with a distributed arrangement of Zugelementaussparungen in a view on a first side of the

Contactor section element.

Fig. 1 shows a schematic representation of a

Cell arrangement 1 of a battery 2. The battery 2 has pressure plates 3 and tension elements 4. In the cell arrangement, a plurality of battery cells 5 are each in one

Battery section 6 arranged side by side. The arranged in a battery section 6 battery cells 5 are connected in parallel with each other. A parallel

Interconnection of the battery cells 5 is through

Contacting section elements 7 allows. For this purpose, end terminals of the battery cells 5 are electrically and thermally conductively connected to the Kontaktierungsabschnittselementen 7. Due to the structure of the cell assembly 1, an electric current and a thermal current particularly well distributed over the entire cell assembly 1.

The contact portion members 7 are respectively

arranged between two battery sections 6. Everyone

Battery section 6 has a height of seven

Battery cells 5 on. Battery cells 5 adjacent

Battery sections 6 are connected in series by the contactor section elements 7 arranged between them. The battery cells 5 in the cell assembly 1 are thus both parallel and serial with each other

interconnected.

A battery start region 8 and a battery end region 9 are replaced by positive end terminals, not shown

or formed by not shown negative end terminals of battery cells 5 in the battery 2. Of the

Battery start region 8 and battery end region 9 are connected to outer contact portion elements 7. The outer contact portion members 7 connect the end terminals of the battery cells 5 electrically and thermally conductive. On a side facing away from the battery starting region 8 or the battery end region 9 side of the outer Kontaktlerungsabschnittselemente 7 each a pressure plate 3 is arranged. The pressure plate 3 is made of copper. So she is very good

thermally conductive.

The printing plates 3 are by means of the tension elements. 4

connected with each other. The tension elements 4 are here

in such a way screwed to the pressure plates 3, that they exert a tensile force on the printing plates 3. This will the cell assembly 1 compressed. In particular, the battery cells 5 are connected to the

Contacting section elements 7 pressed. As a result, a contact area is increased between the end terminals of the battery cells 5 and the Kontaktierungsabschnittselementen 7, so that an electric and a thermal current better between the battery cells 5 and the

Kontaktierungsabschnittselementen 7 flow and thus better over the entire cell assembly 1 can be distributed. This contributes to local thermal

Hot spots within the battery 2 are avoided. Furthermore, due to the invention, caused by the tension elements 4 and the pressure plates 3 pressing the

Cell arrangement 1, the battery 2 of the invention particularly resistant to mechanical stress.

In order to ensure that the battery cells 5 are held securely within the cell assembly 1, the battery cells 5 are enclosed by a plurality of positioning plates 10. The positioning plates 10 enclose the battery cells 5 in the battery sections 6

form-fitting. Because of the

Contacting section elements 7 an exact

Contacting the end terminals of the battery cells 5 with the Kontaktierungsabschnittselementen 7 is necessary, the positioning plates 10 are present in the vicinity of the Kontaktierungsabschnittselementen 7 arranged.

The Kontaktierungsabschnittselementen 7 are conductive structure elements, which in the present case as a flat

Boards are formed. The boards have a core 11 which is led out laterally from the boards. Outside the board, the core 11 forms

Heat removal element 12. Heat can be removed from the cell arrangement 1 via the heat removal element 12. The

Heat removal element 12 has a first planar

Section 13, which is in a plane of

Kontaktierungsabschnittselements 7 is located, and a second flat portion 14, which lies in a further plane which is at a right angle to the plane of

Contacting section element 7 is aligned. The second planar portion 14 is adapted to be thermally conductively connected to a housing (not shown) or to a heat sink (not shown), so that heat flow from the contacting portion 7 to the housing or to the heat sink

can be dissipated.

FIG. 2 shows a schematic representation of a section of the cell arrangement 1 of the battery 2 according to FIG. 1 in a sectional view. In this case, the battery cells 5 are arranged in first cell levels 15 and second cell levels 16. The battery cells 5 in this case directly adjoin one another. The second cell levels 16 each have one

Battery cell 5 less than the first cell levels 15. This results in outer passage portions 17. By the outer passage portions 17 can be traction elements 4 pass. The outer ones

Passage sections 17 allow as many battery cells 5 as possible to be as small as possible

Cross-sectional area of a cell assembly 1 to order. In this way, two passage sections 17 are formed in the second cell plane 16, wherein the second cell plane 16 has only one battery cell 5 less than the adjacent first cell levels 15. By the removal of a battery cell 5 from the second cell level 16th

arise two outer passage portions 17. Through each outer passage portion 17, one or more tension elements 4 can be passed. In the present case, a tension element 4 is passed through each outer passage section 17. In order to achieve a uniform stabilization of the cell assembly 1, however, an internal passage section 18 is provided in the present case, in which no battery cell 5 is arranged. Through the inner passage portion 18 is a tension element 4th

passed through.

The battery cells 5 are enclosed in the battery section 6 by a positioning plate 10. In the

Positioning plate 10 Zugelementaussparungen 19 are provided through which the tension elements 4 are passed in the outer passage portions 17. FIG. 3 shows a schematic representation of a contact-making section element 7 embodied as a circuit board in a view of a first side 20 of FIG

Contactor section element 7. It is

in the present case, a contactor section element 7 for a cell arrangement with battery cells arranged offset in first cell planes and second cell planes. The

Kontaktlerungsabschnittselement 7 is here for

Cell arrangements with four first and three second cell levels suitable, wherein in the first and second cell levels each eight or seven battery cells

are arranged. The contactor section element 7 has Zugelementaussparungen 19, can be passed through the tension elements.

The Kontaktierungsabschnittselement 7 is partially formed of an electrically non-conductive material. On the non-electrically conductive material on the first side of the Kontaktierungsabschnittselements 7 copper is applied as an electrically and thermally conductive material surface. The copper material has several contacting sections 21. These are for

Contacting with the end terminals of the battery cells suitable. For this purpose, the

Contacting sections 21 executed exalted. The

Contacting sections 21 are through

Insulating sections 22 of a non-electric

conductive material separated from a connecting portion 23. The connecting portion 23 is flat

educated. It connects the contacting portions 21 to each other electrically and thermally conductive. Through each insulation portion 22, an electrically and thermally conductive trace 24 is passed, which is dimensioned as a fuse. This will be the

Contacting sections 21 electrically secured against each other.

Around each insulation section 22 and thus also around each contacting section 21 are several

Feedthrough recesses 25 arranged in a circle. In each feedthrough recess 25 is a

Feedthrough element (not shown), which is applied to the feedthrough recess 25. The

Feedthrough element is made of copper and connects the connection portion 23 of the first side 20 of the contactor portion 7 with a second side (not shown) of the first side 20 of the contactor portion 7

Kontaktlerungsabschnittselements 7 electrically and thermally conductive. One from a battery cell in one

Contacting section 21 flowing current can thus through the conductor 24 and the

Contacting portion element to the second side of the Kontaktierungsabschnittselements 7 are guided.

In the Kontaktierungsabschnittselement 7 is a core 11 made of aluminum. The core 11 is of the

Contacting sections 21 and of the

Feedthrough elements electrically isolated. The core extends partially laterally into regions outside of the contacting section element 7. In these regions outside the contacting section element 7, the core 11 forms a heat dissipation element 12. In the present case, four heat dissipation elements 12 are each shown with a first planar section 13. Also on the second side of the Kontaktierungsabschnittselements 7 are the previously

described Zugelementaussparungen 19 visible, can be passed through the tension elements 4. Fig. 4 shows a schematic representation of

Kontaktierungsabschnittselements 7 of FIG. 3 in a view of a second side 26 of the

Contacting section element 7. On the second side 26 of the contacting section element 7, there is formed a copper layer formed as a connecting and contacting section 27. In the connection and

Contacting area 27 are contacting sections 21 arranged, which are suitable for contacting with end terminals of battery cells. To everyone

Contacting section 21 are several

Feedthrough recesses 25 arranged in a circle. The feedthrough recesses 25 are in the

Contacting section element 7 as above

described trained.

In the present case, furthermore, the four heat removal elements 12 are each shown with a first areal section 13. Also on the second page of the

Kontaktierungsabschnittselements 7 are the

Zugelementaussparungen 19 visible, can be passed through the tension elements.

Fig. 5 shows a schematic representation of a

Cross-section of a running as a board

Contacting section element 7 with a

Feedthrough recess 25. The

Contacting section element 7 is merely

shown in sections. The

Contacting section element 7 has an electrically non-conductive substrate material 28. The

Substrate material 28 encloses a core 11 of copper. On a first page 20 of the

Contacting section element 7 forms a

Copper layer has a connecting portion 23. On a second side 26 of the Kontaktierungsabschnittselements 7 a copper layer forms a connection and

Contacting area 27. A feedthrough recess 25 is formed by the contacting portion 7

passed. She goes through the Connecting portion 23 and the connection and

Contacting area 27. On the edge of the

Feedthrough recess 25 is a feedthrough element 29 made of copper applied flat in a thin layer. The feedthrough element 29 is thereby by the

Substrate material 28 is electrically insulated from the core 11. However, a thermal current can flow through the substrate material 28 and over the core 11 of the

Contacting section element 7 are discharged.

FIG. 6 shows a schematic representation of a surface-shaped contacting section element 7 with battery cells 5 resting thereon in a side view. The battery cells 5 have positive end connections 31 and negative end connections 32. Positive end terminals 31 and negative end terminals 32 of the battery cells 5 are electrically and thermally conductively connected to the contacting portion 7. For this they lie on not shown Kontaktierungsabschnitten on the first page and on the second side of the

Contacting section element 7 on. According to the

illustrated embodiment of the

Kontaktierungsabschnittselements 7 are the

Contacting sections, which are connected to positive end terminals 31, in a common plane. The

Contacting sections connected to negative end terminals 32 are also in a common plane. Fig. 7 shows a schematic representation of a

Kontaktierungsabschnitts with step-like surfaces with adjoining battery cells in one Side view. The battery cells 5 have positive

End connections 31 and negative end terminals 32 on.

Positive end terminals 31 and negative end terminals 32 of the battery cells 5 are connected to the

Kontaktierungsabschnittselement 7 electrically and thermally conductively connected. For this purpose, they abut on not-shown contacting sections on the first side and on the second side of the contacting section element 7. According to the illustrated embodiment of the

Kontaktierungsabschnittselements 7 are the

Contacting portions, which are connected to positive end terminals 31, in two different planes, since the first side of the Kontaktierungsabschnittselements 7

is formed step-like. The contacting portions of the contacting portion member 7, which are connected to negative end terminals 32, are also in two different planes, since the second side of the contacting portion 7 is also stepped.

Fig. 8 shows a schematic representation of a

Battery 2 according to the invention with a housing 33. The housing 33 is made of aluminum and encloses a cell arrangement according to the invention

Contacting section elements. In this case, 33 heat removal elements with the housing 33 within the housing

connected so that a thermal current from the

Cell assembly can be removed to the housing 33. The housing 33 is fixedly connected to a holding plate 34, which serves as a heat sink. The housing 33 is at two

End faces closed by pressure plates 3. The

Pressure plates 3 have cooling fins 35, so that the Pressure plates 3 help to cool the cell assembly within the housing 35. Tension elements not shown are passed through the pressure plates 3 and by means of

Nuts 36 bolted to the pressure plates 3. The

Pressure plates 3 are electrical from the tension elements

isolated.

FIG. 9 shows a schematic representation of a contact-making section element 7 embodied as a circuit board with a circular arrangement of tension element recesses 19 in a view of a first side of the drawing

Contactor section element 7. The

Contacting section element points

Contacting portions 21, insulating portions 22, a connecting portion 23 and feedthrough recesses 25, which are formed as in the Kontaktierungsabschnittselement 7 of Fig. 3. The

Contacting section element 7 also has

Pull element recesses 19. The Zugelementaussparungen 19 are substantially circular in the

Contacting section element 7 is arranged. It has been found that with such an arrangement, forces on the contacting section element 7 become more uniform

be distributed as if the Zugelementaussparungen 19 only in edge regions of the

Kontaktierungsabschnittselements 7 are arranged. Due to the arrangement of the Zugelementaussparungen 19 shown, it is avoided that the

Kontaktierungsabschnittselement 7 when pressing the

Cell arrangement bends. Bending could cause individual battery cells within a cell array to become worse or worse be contacted. The illustrated arrangement of Zugelementaussparungen 19 is thus particularly advantageous.

FIG. 10 shows a schematic representation of a contact-making section element 7 embodied as a circuit board with a distributed arrangement of tension element recesses 19 in a view on a first side of the first embodiment

Contactor section element 7. The

Contacting section element 7 points

Contacting portions 21, insulating portions 22, a connecting portion 23 and feedthrough recesses

25, which are formed as in the Kontaktierungsabschnittselement 7 of Fig. 3. The

Contacting section element 7 also has

Pull element recesses 19. The

Zugelementaussparungen 19 are in the

Contacting section element 7 arranged distributed. It has been found that in such an arrangement forces on the Kontaktierungsabschnittselement. 7

be distributed more evenly than if the

Zugelementaussparungen 19 are arranged only in edge regions of Kontaktierungsabschnittselements 7. Due to the arrangement of the Zugelementaussparungen 19 shown, it is avoided that the

Kontaktierungsabschnittselement 7 during pressing of the cell assembly bends. Bending could cause individual battery cells within a cell array to become worse or worse

be contacted. The arrangement shown the

Zugelementaussparungen 19 is therefore as

proved advantageous. LIST OF REFERENCE NUMBERS

1. Cell arrangement

2nd battery

3. pressure plate

4. tension element

5. Battery cell

6. Battery section

7. contacting section element

8. Battery start area

9. Battery end area

10. Positioning plate

11th core

12. Warm discharge element

13. First planar portion of the heat dissipation element

14. Second planar section of the heat removal element

15. First cell level

16. Second cell level

17. Outer passage section

18th inner passage section

19. Zugelementaussparung

20. First side of the contactor section element

21. contacting section

22nd insulation section

23. Connecting section

24. Track

25. Feedthrough recess

26. Second side of the contactor section element

27. Connection and contacting area

28. Substrate material

29. Implementation element 30. Elastic material

31. Positive end connection

32. Negative end connection

33. Housing

34. retaining plate

35. Cooling ribs

36. Mother

Claims

A T E N T A N S P R U C H E

Battery (2) with a cell arrangement (1), wherein the cell arrangement (1) comprises a plurality of battery cells (5), wherein the cell arrangement (1) comprises at least two

Has battery sections (6) and each

Battery section (6) consists of a plurality of battery cells (5), wherein each battery cell (5) has a first and a second end terminal and wherein between the first and the second end terminal each

Battery cell (5) has a battery cell longitudinal axis

runs, wherein the battery cell longitudinal axes of each battery section (6) are each arranged parallel to each other, and wherein the battery sections (6) are arranged adjacent to each other, characterized

characterized in that between at least two

adjacent battery sections (6) at least partially electrically and thermally conductive

Contacting section element (7) having a first side (20) and a second side (26) is arranged on the first side (20) and on the second

Side (26) each having at least one electrically and thermally conductive contacting portion (21), wherein the battery sections (6) are arranged to each other, that each battery section (6) can be assigned a plane perpendicular to the

Battery cell longitudinal axes of the battery cells (5) of the battery section (6) by at least one of

Battery cells (5) of the battery section (6) and extending through this plane to the battery section (6) adjacent battery sections (6) not cut be the first page (20) of this

Contacting section element (7) facing

End connections are electrically and thermally conductively connected to the at least one contacting portion (21) of this first side (20), wherein the second side (26) of this Kontaktierungsabschnittselements (7) facing end terminals electrically and thermally conductive with the at least one

Contacting portion (21) of this second side (26) are connected and wherein end terminals of

Battery cells (5) over the

Kontaktierungsabschnittselement (7) are electrically and thermally conductively connected to each other, so that an electric current and a heat flow over the entire cell assembly (1) are distributed.

Battery (2) according to claim 1, characterized in that the with the at least one

Contacting portion (21) of the first side (20) connected to each other end connections via the

Kontaktierungsabschnittselement (7) are electrically and thermally conductively connected to each other, wherein the at least one

Contacting section (21) of the second side (26) connected to each other end connections via the

Kontaktierungsabschnittselement (7) are electrically and thermally conductively connected to each other, and wherein the at least one

Contacting portion (21) of the first side (20) connected to the end terminals electrically and thermally conductive with the at least one

Contacting section (21) of the second side (26) connected end connections via the

Kontaktierungsabschnittselement (7) are connected, so that the battery cells (5) in an electrical series and parallel connection are electrically conductively connected to each other and also thermally conductively connected to each other.

Battery (2) according to one of the preceding claims, characterized in that adjacent ones

Battery sections (6) from each other in the direction of a battery cell longitudinal axis of one of the adjacent

Battery sections (6) are spaced.

Battery (2) according to one of the preceding claims, characterized in that the battery cells (5) of adjacent battery sections (6) are arranged so that at least one by a battery cell (5) of a battery section (6) extending axis, which is parallel to a battery cell longitudinal axis this

Battery cell (5) extends, a battery cell (5) in an adjacent battery section (6) intersects.

Battery (2) according to one of the preceding claims, characterized in that the battery cells (5) of adjacent battery sections (6) to each other

opposite to one

Contacting section element (7) abut.

Battery (2) according to one of the preceding claims, characterized in that the battery cells (5) of all battery sections (6) of the battery (2) to each other have parallel aligned battery cell longitudinal axes.

7. Battery (2) according to claim 6, characterized in that the battery sections (6) of the battery (2) are arranged one behind the other along a battery axis, which runs parallel to the battery cell longitudinal axes. 8. Battery (2) according to claim 7, characterized in that all the battery sections of the battery in one

Battery chamber lie, wherein a battery compartment cross-section of the battery compartment perpendicular to the battery axis a maximum battery section cross section of a

Battery section cross-section of a battery section is the all battery section cross-sections of all battery sections along the battery axis

includes.

9. Battery (2) according to any one of the preceding claims, characterized in that the first end terminals of the battery cells (5) Batteriepluspole and the second

Terminal connections of the battery cells (5) form battery inlets, wherein the battery cells (5) of a

Battery section (6) with a

Contacting section element (7) respectively

are connected exclusively via Batteriepluspole or exclusively via Batterieininuspole.

10. Battery (2) according to one of the preceding claims, characterized in that the

Contacting section element (7) is plate-shaped.

11. Battery (2) according to one of the preceding claims, characterized in that the

Contacting section element (7) has planar sections, which are arranged step-like offset from each other on the Kontaktierungsabschnittselement (7).

12. Battery (2) according to one of the preceding claims, characterized in that on a

Battery start area (8) and a

Batterieendbereich (9) of the cell assembly (1) each have a pressure plate (3) is arranged, wherein the

Pressure plates (3) via tension elements (4) are interconnected and thereby applied to the at least one Kontaktierungsabschnittselement (7)

Battery cells (5) to the at least one

Contacting section element (7) press, and wherein the battery starting area (8) and the

Batterieendbereich (9) through end connections at a first end and at a second end of

Cell arrangement (1) can be defined.

13. Battery (2) according to one of the preceding claims and claim 7, characterized in that the

Battery cells (5) in the battery sections (6) in first and second cell planes (15, 16) are arranged, wherein the first and the second cell planes (15, 16) alternately within a battery section (6) are arranged along each cell level

at least two battery cells (5) are arranged, wherein between adjacent battery cells (5) in the first cell level (15) and adjacent

Battery cells (5) in the second cell plane (16) is given an equal distance, wherein the

Battery cells (5) in the first cell plane (15) offset from the battery cells (5) in the second cell plane (16) are arranged, and wherein the battery cells (5) in all battery sections (6) are arranged identically, so that within the lateral surface at least an outer passage portion (17) is formed through which one of the tension members (4) is passed. 14. Battery (2) according to one of claims 1 to 12,

characterized in that the battery cells (5) abut in corner regions of the battery sections (6) on two other battery cells (5) and in edge regions of the battery sections (6) on three others

Battery cells (5) abut and that all

Battery cells (5), which are not arranged in a corner region or an edge region, abut six other battery cells (5). 15. Battery (2) according to one of the preceding claims, characterized in that the end connections of a

Battery section (6) abut directly to end terminals of an adjacent battery section (6) electrically and thermally conductive.

16. Battery (2) according to one of the preceding claims, characterized in that in the cell arrangement (1) at least one positioning plate (10) is arranged through which the battery cells (5) of the

Battery section (6) are passed, wherein the positioning plate (10) has at least one recess for passing through at least one battery cell (5), and that the recess is defined by an envelope around the battery cells (5) of the battery section (6), wherein the Recess at least one battery cell (5) engages positively around the at least one battery cell (5) within the

Battery (2) to position and stabilize.

17. Battery (2) according to claim 16, characterized in that on each contacting section element (7) on both sides in each case a positioning plate (10) is arranged.

18. Battery (2) according to one of the preceding claims, characterized in that at least one

Kontaktierungsabschnittselement (7) is thermally conductive via a heat removal element (12) connected to a heat sink.

19. Battery (2) according to any one of the preceding claims, characterized in that the cell assembly (1) by a thermally conductive housing (33) is enclosed.

20. Battery (2) according to claim 18 and claim 19, characterized in that the heat dissipation element (12) with the

Housing (33) is connected.

21. Battery (2) according to one of the preceding claims, characterized in that the

Kontaktierungsabschnittselement (7) is designed as a metal body.

22. Battery (2) according to one of claims 1 to 20,

characterized in that the

Contacting section element (7) as a

Conductor element is formed, which consists partly of a non-electrically conductive material, wherein the conductor forming element on a first

Side (20) and on a second side (26) each having at least one electrically and thermally conductive contacting portion (21), and wherein each contacting portion (21) with each other

Contacting portion (21) is electrically and thermally conductively connected.

23. Battery (2) according to claim 22, characterized in that in the non-electrically conductive material of

Conductor element is a core (11) made of an electrically and thermally conductive material, wherein on the core (11) facing away from the not

each electrically conductive material, the at least one contacting portion (21) is arranged, and wherein at least one electrically and thermally

conductive feedthrough element (29) extends through the core (11) and through the non-electrically conductive material arranged on both sides of the core (11), the feedthrough element (29) being electrically insulated from the core (11) and being electrically conductive with the latter at least one Contacting section (21) on the first side (20) and with the at least one

Contacting portion (21) on the second side (26) is connected, so that an electrically and thermally conductive connection of the contacting portions (21) on the first side (20) with the

Contacting sections (21) on the second

Side (26) through the lead-through element (29)

is produced and a heat flow through the core (11) can be picked up and removed from the conductor forming element.

24. Battery (2) according to one of claims 22 or 23,

characterized in that on the first side (20) of the conductor forming element at least two

Contacting sections (21) and an electrically and thermally conductive connecting section (23)

are arranged, which electrically and thermally conductively connects the contacting portions (21) on the first side (20) to each other

Contacting portion (21) on the first side (20) is associated with an electrical fuse (24) and that the connecting portion (23) with each

Contacting section (21) via a this

Contacting section (21) associated electrical

Fuse (24) is connected, wherein the

Connecting portion (23) with the at least one

Contacting section (21) on the second side (26) by the non-conductive material of

Conductor element electrically conductively connected via an electrically conductive feedthrough element (29), so that each contacting portion (21) on the first page (20) opposite each other

Contacting portion (21) on the first side (20) of the conductor forming member and opposite each

Contacting section (21) on the second side (26) of the conductor forming element by at least one

electrical fuse is secured.